You can transform `reverse . take n . reverse`

by treating your list as a particularly obtuse lazy natural number: empty lists are zero, and conses are succ. For lazy naturals encoded as lists, subtraction is `drop`

:

```
type LazyNat a = [a]
lengthLazy :: [a] -> LazyNat a
lengthLazy = id
dropLazy :: LazyNat a -> [b] -> [b]
dropLazy [] xs = xs
dropLazy (_:n) (_:xs) = dropLazy n xs
dropLazy _ _ = []
-- like Prelude.subtract, this is flip (-)
subtractLazy :: Int -> LazyNat a -> LazyNat a
subtractLazy = drop
```

Now we can easily implement the "take last `n`

" function:

```
takeLast n xs = dropLazy (subtractLazy n (lengthLazy xs)) xs
```

...and you'll be pleased to know that only `n`

conses need to be in memory at any given time. In particular, `takeLast 1`

(or indeed `takeLast N`

for any literal `N`

) can run in constant memory. You can verify this by comparing what happens when you run `takeLast 5 [1..]`

with what happens when you run `(reverse . take 5 . reverse) [1..]`

in ghci.

Of course, I've tried to use very suggestive names above, but in a real implementation you might inline all the nonsense above:

```
takeLast n xs = go xs (drop n xs) where
go lastn [] = lastn
go (_:xs) (_:n) = go xs n
go _ _ = []
```

`last`

is the only one, it should run in constant space and O(n) time; but if some other consumer holds a reference to this list, it will come into existence whole when`last`

enumerates over it to its last cell. Thus O(n) space and time. Similarly for the`takeLast`

shown in Daniel Wagner's answer. -- Or we can change theactual implementationof lists, as self-balancing trees with index used as key, with obvious consequences. Clojure uses even cleverer trees with high branching factor (32?). – Will Ness Nov 12 '13 at 21:30